Electrochemical Detection of Chloramphenicol with Different Modified Electrodes Based on the Metal-Cyclotriveratrylene Framework and Mesoporous Carbon
Yuying Li, Xia Niu, Wen-Yuan Pei, Jian‐Fang Ma
Abstract
Design of high-performance electrochemical sensors for detection of antibiotics is greatly desirable for human health and ecological safety. Herein, a new metal–organic framework (MOF), namely, [Zn 2 L(PDC) 2 (H 2 O) 2 ]·3H 2 O ( 1 ), was synthesized with isophthalic acid (H 2 PDC), Zn(II) cation, and cyclotriveratrylene-based ligand (L). By mechanical milling, 1 was incorporated with mesoporous carbon (MC) to produce 1 @MC. Subsequently, 1 @MC was decorated on different bare electrodes (glass carbon (GC), Au, Pt, or W electrode). The introduction of MC significantly improved the conductivity and the current response intensity for determination of chloramphenicol (CAP). Among these sensors, the current responses of CAP on 1 @MC(1:2)/GCE and 1 @MC(1:2)/Au were more intense. Markedly, they exhibited relatively wide linear ranges (0.5–400 μM on 1 @MC(1:2)/GCE and 1–400 μM on 1 @MC(1:2)/Au) and low limits of detection (0.15 μM on 1 @MC(1:2)/GCE and 0.48 μM on 1 @MC(1:2)/Au). Particularly, they can be used for the measurement of CAP in eye drop and milk sample with fine recoveries.